* Astronomy

An international team of astronomers released today (15 May) new results on the Cosmos, based on the largest map of the heavens ever produced.

This massive atlas emphatically confirmed recent findings that the Universe is full of ’dark energy’, a mysterious substance that makes up three-quarters of our Universe, together with ’dark matter’ which accounts for most of the remaining quarter. Understanding this composition is now one of the most important problems facing the whole of science.


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"We now have a precise view of what makes up our Universe, but little idea as to why. It is intriguing that the ordinary matter our bodies are made of and that we experience in everyday life only accounts for a few percent of the total cosmic budget" - Prof. Ofer Lahav, a member of the international team and the Head of the Astrophysics Group at University College London.

Our Universe contains billions of galaxies of all shapes and sizes. In recent years astronomers have used increasingly large surveys to map out the positions of these galaxies, stepping their way out into the Cosmos.
The new cosmic map unveiled today is the largest to date -- a three-dimensional atlas of over a million galaxies spread over a distance of more than 5 billion light years. The findings confirm that we live in a Universe filled with mysterious dark matter and dark energy.

"We have analysed the patterns in this map and discovered waves of structure over a billion light years across. These waves were generated billions of years ago and have been vastly stretched in size by the expanding Universe" - Dr. Chris Blake of the University of British Columbia, principal author of the study.

Construction of the cosmic atlas was led by co-author Dr. Adrian Collister of the University of Cambridge, as part of his PhD work, using a novel Artificial Intelligence technique he developed with his supervisor Prof. Ofer Lahav.

"By using very accurate distances of just 10,000 galaxies to train the computer algorithm we have been able to estimate reasonably good distances for over a million galaxies. This novel technique is the way of the future" - Dr. Adrian Collister.

The original 2-dimensional positions of colours of the one million galaxies were from the Sloan Digital Sky Survey.
The precise observations of the 10,000 galaxy distances were made as part of an international collaboration between U.S., U.K. and Australian teams using data from the Sloan Digital Sky Survey and the Anglo-Australian Telescope.
By measuring the positions of galaxies, astronomers can unravel the balance of forces that govern our Universe: the force of gravity which pulls everything together, and the competing effect of the expanding Universe which smoothes things out. These cosmic forces have arranged the galaxy distribution into a complex network of clusters, filaments and voids.

"The galaxy map can tell us the amount of ordinary ’baryonic’ matter relative to the amount of mysterious ’dark matter’. We have confirmed that over 80% of the material in the Universe consists of an invisible dark matter whose nature is not yet understood” - co-author Dr. Sarah Bridle, University College London.

The cosmic atlas of a million galaxies will shortly be made freely available on the World Wide Web for the benefit of other researchers. This free exchange of data is an important feature of modern astronomy, since many discoveries are only possible when different observations are combined.
The key problem in mapping the cosmos is determining the distance to each galaxy. Researchers can measure these distances because as the Universe expands, the colour of each galaxy changes as their emitted light waves are stretched or ‘redshifted’.

Traditionally, astronomers have needed to take a "spectrum" of each galaxy to determine this distance, splitting its light into many components to reveal sharp features with which to measure the amount of redshifting. This requires a time-consuming, individual observation of each galaxy.
The new cosmic map has been constructed using a novel technique focusing on a special class of galaxy whose intrinsic colour is very well known. For these ‘Luminous Red Galaxies’ researchers can measure the amount of colour distortion, and hence the approximate distance of the galaxy, just by looking at digital images of the sky, without the need to obtain a full spectrum.

All that is needed to exploit the technique is accurate observations of a small sample of the galaxies. In this case, precise measurements of just 10,000 galaxies were used to produce the atlas of over a million galaxies. These techniques will be very important for future large astronomical projects such as the Dark Energy Survey, scheduled to start in 2009, in which University College London and the universities of Portsmouth, Cambridge and Edinburgh are key partners.

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Cosmological parameters from a million photometric redshifts of SDSS LRGs
Authors: Chris Blake (UBC), Adrian Collister (IoA), Sarah Bridle (UCL), Ofer Lahav (UCL)

We analyse MegaZ-LRG, a new photometric-redshift catalogue of Luminous Red Galaxies (LRGs) based on the imaging data of the Sloan Digital Sky Survey (SDSS) 4th Data Release. MegaZ-LRG, presented in a companion paper, contains > 10^6 photometric redshifts derived with ANNz, an Artificial Neural Network method, constrained by a spectroscopic sub-sample of ~13,000 galaxies obtained by the 2dF-SDSS LRG and Quasar (2SLAQ) survey. The catalogue spans the redshift range 0.4<z<0.7 with an r.m.s. redshift error ~ 0.03(1+z). We present the first cosmological parameter fits to galaxy angular power spectra from a photometric redshift survey. Combining the redshift slices with appropriate covariances, we determine the matter density Omega_m and baryon density Omega_b in the combinations Omega_m h = 0.20 ±0.03 and Omega_b/Omega_m = 0.14 ±0.04. These results are in agreement with and independent of the latest studies of the Cosmic Microwave Background radiation, and their precision is comparable to analyses of contemporary spectroscopic-redshift surveys. We find visual suggestions of baryon oscillations in the clustering pattern, with a "model-independent" statistical significance of less than 3 sigma. On the largest scales probed by the survey we measure an excess of power with respect to the model with a significance of approximately 2 sigma. We perform an extensive series of tests which conclude that our power spectrum measurements are robust against potential systematic photometric errors in the catalogue. We conclude that photometric-redshift surveys are competitive with spectroscopic surveys for measuring cosmological parameters in the simplest "vanilla" models. Future deep imaging surveys have great potential for further improvement, provided that systematic errors can be controlled.

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Dark energy and dark matter, two of the greatest mysteries confronting physicists, may be two apects of the same phenomena; as a yet undiscovered kind of star , that could also in turn, remove the need for black holes.

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The Gravastar theory is a proposal by Pawel Mazur and Emil Mottola to replace the black hole. Instead of a star collapsing into a pinpoint of space with virtually infinite density, the gravastar theory proposes that as an object gravitationally collapses, space itself undergoes a phase transition preventing further collapse, being transformed into a spherical void surrounded by a form of super-dense matter.

http://en.wikipedia.org/wiki/Gravastar

Dark energy, the mysterious stuff invoked to explain why the expansion of the universe is accelerating, could have a simple explanation. The energy may be coming from neutrinos that were created in copious quantities just after the big bang.
The leading candidate for dark energy is Einstein's "cosmological constant", which proposes that the vacuum of space has an inherent energy that counters gravity.
But if you calculate the density of this energy using quantum theory, it works out at nearly 120 orders of magnitude greater than what would fit with cosmological observations. So physicists have proposed ever more exotic explanations for dark energy that require, for instance, the existence of extra dimensions.

Now a team of Italian physicists says the answer has been under our noses all along. Antonio Capolupo and Giuseppe Vitiello of the University of Salerno and Salvatore Capozziello at the University of Naples claim that dark energy is the result of Neutrino 'mixing' that leads to a non-zero contribution to the cosmological constant. This contribution is of a completely different nature with respect to the usual one by a massive spinor field.

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Neutrino mixing as a source for cosmological constant
Authors: Massimo Blasone, Antonio Capolupo, Salvatore Capozziello, Sante Carloni, Giuseppe Vitiello

We report on recent results showing that neutrino mixing may lead to a non-zero contribution to the cosmological constant. This contribution is of a completely different nature with respect to the usual one by a massive spinor field. We also study the problem of field mixing in Quantum Field Theory in curved space-time, for the case of a scalar field in the Friedmann-Robertson-Walker metric.

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Constraining Inverse Curvature Gravity with Supernovae
Authors: Olga Mena, Jose Santiago, Jochen Weller

Researchers show that the current accelerated expansion of the Universe can be explained without resorting to dark energy.

Models of generalized modified gravity, with inverse powers of the curvature can have late time accelerating attractors without conflicting with solar system experiments. they have solved the Friedman equations for the full dynamical range of the evolution of the Universe. This allows them to perform a detailed analysis of Supernovae data in the context of such models that results in an excellent fit.
Hence, inverse curvature gravity models represent an example of phenomenologically viable models in which the current acceleration of the Universe is driven by curvature instead of dark energy.
When they further include constraints on the current expansion rate of the Universe from the Hubble Space Telescope and on the age of the Universe from globular clusters, they obtain that the matter content of the Universe is 0.07